1η Ημέρα
1. Let 
be positive real numbers such that 
. Prove that
2. An integer is assigned to each vertex of a regular pentagon so that the sum of the five integers is 2011. A turn of a solitaire game consists of subtracting an integer
from each of the integers at two neighboring vertices and adding 
to the opposite vertex, which is not adjacent to either of the first two vertices. (The amount and the vertices chosen can vary from turn to turn.) The game is won at a certain vertex if, after some number of turns, that vertex has the number 2011 and the other four vertices have the number 0. Prove that for any choice of the initial integers, there is exactly one vertex at which the game can be won.
3. In hexagon
, which is nonconvex but not self-intersecting, no pair of opposite sides are parallel. The internal angles satisfy 
, 
, and 
. Furthermore 
, 
, and 
. Prove that diagonals 
, 
, and 
are concurrent.
2η Ημέρα1. Consider the assertion that for each positive integer 
, the remainder upon dividing 
by 
is a power of 4. Either prove the assertion or find (with proof) a counterexample.
2. Let
be a given point inside quadrilateral 
. Points 
and 
are located within such that
Prove that
if and only if 
.
3. Let
be a set with 
, meaning that has 225 elements. Suppose further that there are eleven subsets 
of such that 
for 
and 
for 
. Prove that 
, and give an example for which equality holds.
be positive real numbers such that . Prove that2. An integer is assigned to each vertex of a regular pentagon so that the sum of the five integers is 2011. A turn of a solitaire game consists of subtracting an integer
from each of the integers at two neighboring vertices and adding to the opposite vertex, which is not adjacent to either of the first two vertices. (The amount and the vertices chosen can vary from turn to turn.) The game is won at a certain vertex if, after some number of turns, that vertex has the number 2011 and the other four vertices have the number 0. Prove that for any choice of the initial integers, there is exactly one vertex at which the game can be won. 3. In hexagon
, which is nonconvex but not self-intersecting, no pair of opposite sides are parallel. The internal angles satisfy , , and . Furthermore , , and . Prove that diagonals , , and are concurrent., the remainder upon dividing by is a power of 4. Either prove the assertion or find (with proof) a counterexample.2. Let
be a given point inside quadrilateral . Points and are located within such thatProve that
if and only if . 3. Let
be a set with , meaning that has 225 elements. Suppose further that there are eleven subsets of such that for and for . Prove that , and give an example for which equality holds. 
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